Device and method for correcting obstructive sleep apnea

ABSTRACT

An orthotic obstructive sleep apnea treatment device is provided that includes a hyoid bone attachment element disposed to attach a ferric element to a hyoid bone whereby the ferric element force can be adjusted by a force delivery element.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 15/600,964 filed May 22, 2017, now U.S. Pat. No. 10,500,086 issued Dec. 10, 2019, which is incorporated herein by reference.

U.S. patent application Ser. No. 15/600,964 is a continuation of U.S. patent application Ser. No. 14/555,835 filed Nov. 28, 2014, now U.S. Pat. No. 9,655,767 issued May 23, 2017, which is incorporated herein by reference.

U.S. patent application Ser. No. 14/555,835 filed Nov. 28, 2014 is a continuation of U.S. patent application Ser. No. 14/338,188 filed Jul. 22, 2014, now abandoned, which is incorporated herein by reference.

U.S. patent application Ser. No. 14/338,188 filed Jul. 22, 2014 is a continuation of U.S. patent application Ser. No. 12/930,834 filed Jan. 18, 2011, now U.S. Pat. No. 8,808,158 issued Aug. 19, 2014, which is incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates generally to a method and device for treatment of sleep disorders. More particularly the invention relates to a method and device for the treatment of snoring, and obstructive sleep apnea.

BACKGROUND OF THE INVENTION

Obstructive sleep apnea (“OSA”) is a disorder characterized by repeated upper airway obstruction during sleep. OSA is a serious and life-threatening breathing disorder that affects an estimated 20 million American adults.

OSA is associated with significant adverse impacts on health and daily function including daytime sleepiness, decreases in quality of life, headaches, and serious health effects such as cardiovascular disease (hypertension, myocardial infarction, and cerebrovascular accident), endocrine disease, and death. Men, the elderly, and the obese are at elevated risk. Snoring is a related, albeit less severe, disorder that can be associated with partial airway obstruction, and it affects millions more. Therapies that treat OSA may also be effective treatments for snoring.

Current treatment methods—which range from over-the-counter oral and nasal supports to complicated surgeries—tend to be poorly tolerated and/or of limited effectiveness. These concerns may constitute barriers to diagnosis and treatment. There is a need for better OSA therapies to alleviate the suffering of individuals with OSA and also provide benefits to their families, employers, the medical infrastructure, and society at large.

The market for treatments of OSA and snoring is currently experiencing a period of unprecedented growth due both to the increasing percentage of Americans affected by the risk factors for OSA (obesity, advanced age) and to greater awareness of the conditions by medical providers and patients. As both groups have recognized the consequences of OSA and snoring, there has been a greater focus on diagnosis and treatment.

Sleep is associated with a number of physiologic changes, including the loss of upper airway muscle tone and changes in neuromuscular reflexes that can result in upper airway obstruction and snoring. In many patients with OSA and snoring, the relaxation of muscles and other changes lead to collapse of various structures around the throat and contribute to blockage of breathing and/or vibration of structures.

Current treatments for OSA and snoring include non-invasive solutions that are either only minimally effective (e.g. external nasal dilator strips or jaw-advancing appliances), efficacious but poorly tolerated (e.g. positive airway pressure therapy), or surgery (e.g. uvulopalatopharyngoplasty) that can be ineffective, invasive, costly, associated with substantial side effects, and non-reversible.

Positive Airway Pressure (“PAP”) techniques and devices are commonly used in the industry. Useful variations include BiPAP and AutoPAP. PAP is administered by means of a mechanical unit that delivers pressurized room air to the upper airway through an interface (e.g. nasal mask) that is worn by the patient during sleep. Pressurized air functions as a pneumatic splint to maintain airway patency. PAP is highly efficacious, but unfortunately long-term acceptance of this treatment and compliance are often poor. Studies have shown that between 20% and 70% of patients fail to use nasal CPAP as prescribed. Problems associated with PAP include an inability to fall asleep while wearing the device, excessive dryness of the mouth and throat, mucous congestion, sinusitis, and unconscious removal of the device during the night. Nonetheless, the market for CPAP devices is enormous and has sprouted several large companies.

One attempt to address the needs in the art teach using a magnet secured to an endotracheal tube, which is passed though the throat so that the tube can maintain a patient airway. Because the tube is subject to dislodgment, an external neckband containing a magnet was configured to attract the magnet in the tube so that tube is not subject to extubation.

Another attempt to address the needs using magnets include the use of multiple implanted magnets. Problems with prior art attempts when multiple magnets are implanted in a patient include (1) continuous force, (2) proximity will increase magnetic interaction and (3) attractive or repulsive magnetic interaction can result in migration of the magnets. The application of continuous force may be unnecessary (cannot be readily discontinued when an apnea correction is not needed during sleep or while awake) or result in adverse consequences (for example, resulting in changes in voice or difficulty swallowing). In (2) and (3), magnetic attractive force increases as attractively oriented magnets approach each other. For magnets in soft tissue, this can lead to an accelerating process, with greater increases in attractive forces as the distance between the magnets decreases. Such attractive forces will increase the tendency of such attractive magnets to migrate, exacerbating this problem.

Other non-surgical treatments for sleep apnea include the use of mandibular repositioning devices and other oral appliances that hold and/or pull the jaw or tongue in a forward position to open the airway by reducing collapse of the soft palate, tongue, and/or other structures. These devices also suffer from uneven compliance rates and can be associated with changes in dental occlusion, dental pain, and inflammatory or degenerative changes in the temporomandibular joint.

Surgical procedures can be performed to treat OSA and snoring, and the selection is based on a number of factors, including the procedure's benefits and the individual patient's pattern of upper airway obstruction, whether at the palate and/or tongue (aka retrolingual, retroglossal, or hypopharyngeal) regions. Tracheotomy was the first OSA treatment; although highly effective, tracheotomy carries untoward social, and in some cases medical, side effects and is not performed commonly for OSA treatment. Uvulopalatopharyngoplasty (“UPPP”) is the most common procedure performed to treat OSA. The procedure involves removal of the palatine tonsils, with resection and/or repositioning of the uvula and soft palate. The procedure can increase the airway dimensions at the palate region but does not address obstruction well in the tongue region, the portion of the throat located more inferiorly.

A number of techniques and technologies have been developed to treat the tongue region. One approach utilizes radiofrequency energy to shrink and/or stiffen the soft palate and tongue. Radiofrequency energy can be used to create coagulative lesions at specific locations, and the healing process creates fibrosis and the associated tissue shrinkage and stiffening. Radiofrequency technologies can also be used to resect tongue tissue and reduce tongue size. Although effective in some, radiofrequency procedures have not performed well in the large majority of OSA patients.

Another OSA surgical approach to the tongue region is pulling the tongue anteriorly or otherwise preventing the posterior tongue prolapse that can occur with the loss of muscle tone during sleep. The most recent significant such surgical system was approved by the FDA in February 1998. Known as the tongue suspension or stabilization procedure (with the trade name Repose), it is intended to pull the tongue forward and/or stabilize the tongue in place, thereby keeping the tongue from falling into the airway during sleep. The system utilizes a bone screw inserted into the mandible. The screw attaches to a non-absorbable suture, which travels the length of the tongue and back. A similar application of this technique uses two bone screws attached to the mandible to pull the hyoid bone anteriorly and superiorly. Maxillomandibular advancement is an effective but highly invasive procedure, and the procedure's substantial morbidity and risks have limited its widespread adoption.

Techniques have also been developed for treating the soft palate with palatal implants. One attempt is a method for treating snoring of a patient, which includes embedding an implant into the patient's soft palate in order to alter the dynamic response of the soft palate to airflow. Other techniques and technologies rely on the use of chemical or thermal (including radiofrequency) injury of the soft palate to shrink and/or stiffen the palate, primarily to treat snoring but not OSA.

These treatments have demonstrated limited effectiveness and, in some cases, high morbidity, contribute to an ongoing need for more effective treatments for OSA and/or snoring.

SUMMARY OF THE INVENTION

To address the needs in the art, an orthotic obstructive sleep apnea treatment device is provided. The device has a hyoid bone attachment element to couple a ferric element to a hyoid bone. An external orthotic neck device is provided that has a support shaped to confirm about one or more of a neck, a head, or a chest of a human subject. The support has a force delivery element configured to be disposed at an exterior region of the human subject. The force delivery element provides an attractive or adjustive force to the ferric element. A sensor is included for measuring one or more metrics associated with a breathing pattern, a breathing rate, an apnea event, a snoring pattern or a snoring rate.

In one embodiment, the force delivery element has an electromagnet, and an attractive force exerted by the electromagnet is adjustable according to an electrical current. In this embodiment, an amperage of the electrical current can be determined according to (i) data from the sensor or (ii) to a predetermined pattern, whereby the predetermined pattern has data from a pattern analysis.

In another embodiment, an inflatable bladder between the human subject and support is provided. The inflatable bladder can be adjusted manually or automatically to vary the ferric element distance and therewith the attractive or adjustive force.

In yet another embodiment, the support has a force sensor.

In yet another embodiment, the sleep apnea treatment device further has a force frequency sensor to quantify the one or more metrics.

In yet another embodiment, the sleep apnea treatment device further has a pulse sensor, an oxygen sensor, an acoustic sensor, an accelerometer sensor, or a touch sensor.

In yet another embodiment, the sleep apnea treatment device further has a sensor to detect a physiological position of tissue of said human subject.

In yet another embodiment, the sleep apnea treatment device further has a telemetric sensor, whereby the telemetric sensor is magnetic, capacitive or electric field based.

In yet another embodiment, the support comprises an embedded microprocessor.

In yet another embodiment, the support has a processor and a memory device. The processor and the memory device are disposed to monitor data from the sensor, whereby the processor and the memory device outputs measurement data according to time. The support could have a visual display, and the processor and the memory device could output measurement data to the visual display. The said visual display could have indicator lights, whereby the indicator lights provide acceptable or unacceptable display signals according to readings from the sensor. The support could have connectivity to an external computer and a data storage device, whereby the connectivity could have wired connectivity or wireless connectivity, whereby the data from the sensor is communicated to and from the external computer and the external storage device. The external computer could be a cellular telephone.

In yet another embodiment, the force delivery element could have a processor and a memory device whereby data from the sensor is processed through the processor and the memory device. The attractive or adjustive force could be adjusted according to instructions from the processor and memory. The processor and memory could be configured to provide pattern recognition, whereby the pattern recognition identifies a pattern associated with breathing rate of the human subject. The recognized pattern from the pattern recognition could be configured to be output for analysis. The attractive or adjustive force could be configured according to said recognized pattern.

In yet another embodiment, the force delivery element could have an adjustable force element, whereby the adjustable force element has a moveable magnet.

In yet another embodiment, the force delivery element could have a removable magnet, whereby the force delivery element could be disposed to receive magnets having different magnetic forces.

In yet another embodiment, the support could have a localized shape adjustment member, whereby the localized shape adjustment member could be disposed to conform about the neck.

In yet another embodiment, the force delivery element could have a processor and a memory device, whereby data from the sensor could be configured to be processed through the processor and the memory device, and whereby an inflatable balloon bladder is configured to be adjusted according to the data from the sensor.

In yet another embodiment, the force delivery element could have an adjustable magnet, whereby the adjustable magnet is disposed in (i) a threaded positioner or (ii) an indexed positioner.

In still another embodiment, the force delivery element could have a processor and a memory device both configured to recognize patterns associated with the one or more metrics.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a planar view of a hyoid bone

FIGS. 2a-2b show planar schematic views an orthotic obstructive sleep apnea treatment device, according to one embodiment of the invention.

FIGS. 3a-3b show some exemplary embodiments of the external orthotic neck device, according to the current invention.

FIGS. 4a-4c show an exemplary attachment element to secure implant device to the hyoid bone, according to one embodiment of the invention.

FIGS. 5a-5c show other exemplary embodiments of the invention.

FIG. 6 shows a housing that includes an inflatable balloon bladder disposed to conform about the neck of a patient, according to the current invention.

FIGS. 7a-7f show some exemplary embodiments of the external orthotic neck device, according to the current invention.

FIGS. 8a-8d show the housing having an exemplary embodiment of an adjustable force delivery element, according to the current invention.

FIGS. 9a-9d show an exemplary housing disposed to receive force delivery elements, according to the current invention.

DETAILED DESCRIPTION

The current invention provides an external orthotic device for pulling on the hyoid bone using an internally implanted magnet attached to the hyoid. The device cradles an external magnet whereby the distance between the internal and external magnet can be adjusted by adjusting the external device, moving the cradled external magnet closer to or farther away from the implanted magnet, and thus adjusting the force applied to the hyoid.

The orthotic device has a shape or multiple shapes that fits a wide spectrum of anterior neck configurations. The shape of the device minimizes and/or avoids contact pressure over the hyoid bone and other structures that are secured directly to an internal ferric element. The ferric element could be either permanently magnetized (e.g. rare-earth magnets) or it could be a magnetically susceptible material that becomes magnetized when exposed to the magnetic field of the external device (e.g. a paramagnetic material such as steel).

According to the invention, the device is disposed to adjust the pull on the hyoid bone, where the pull is strong enough and in an appropriate direction to maintain airway patency.

In another aspect of the invention, the device is disposed to adjust the compression of tissue between the internal implanted magnet and the external device, where damage to the skin and subcutaneous tissue is avoided by restricting the compressive pressure between the two magnets. Further, the device is disposed to adjust the pressure exerted on tissue supporting the device, where the pressure is low enough to avoid damaging the tissue.

In another aspect of the invention, the device is disposed to sense the magnitude, direction and distribution of force imposed on the hyoid bone. By sensing minimum tension, and further sensing breathing or snoring, the device provides adjustability in the force imposed on the hyoid bone, where a single setting may not be appropriate over the long term, whether due to tissue edema, weight changes, sleeping position and breathing type, or other factors that can affect airway collapsibility.

The current invention provides for monitoring and adjusting different forces exerted on a patient, where these forces include: the force of pull on the hyoid such that it is equal to the elastic restoration forces on the hyoid at the required hyoid displacement; a compression pressure of tissue between the magnets or ferric elements, where the pressure is determined by the magnetic force divided by the surface area over which it is spread; and a surface pressure on tissue supporting the devices, where the total supporting force is equal to the required force of pull on the hyoid. Here, the pressure is equal to the force divided by the total surface area over which it is spread.

According to the invention, an important force or pressure to measure for safety is the compression of tissue between ferric elements. In some applications the external magnet may be close enough to the ferric element that the skin and subcutaneous tissue will be compressed between the two magnets. The maximum compressive pressure will occur at the minimum distance between the magnets, which will be determined by the strength of the magnets and the compressibility of the tissue. The current invention provides safety features that ensure this maximum compressive pressure be sufficiently low to avoid tissue damage, where the pressure is equal to the magnetic force divided by the surface area over which the force is spread.

As the external magnet is pulled away from the skin, the internal ferric element will move with it (hence maintaining the same compressive pressure) until the elastic restoration forces pulling the hyoid towards the hyoid's resting position are greater than the magnetic forces between the two magnets.

When the internal magnet has been pulled so far that the elastic restoration forces pulling the hyoid back towards its resting position are greater than the magnetic forces pulling the internal ferric element towards the external magnet, the two elements will start to be pulled apart. As the magnet is pulled farther away, the compression of tissue between the two magnets will decrease. Eventually, there will be no compression and the external magnet will lift off the skin. Eventually, the elastic restoration forces will exceed the forces of the external magnet acting on the internal ferric element (which falls off rapidly as 1/r²) and the hyoid will relax to its resting position.

The current invention addresses the instance, where, when the magnetic forces are greater than the pull force, the external magnet sits on the skin. The advantage of the invention is that the distance between the magnet and ferric element (and hence the forces) will be determined by the compressibility of the tissue and will be static in time.

The present invention uses the attraction between an implanted ferric material component and an external magnetic component to keep the airway open and prevent airway collapse. The external component includes a neck accessory that is readily placed or removed to make the device active or inactive, respectively. According to one embodiment an internal magnet and an external magnet are provided. In another embodiment, an internal ferric material and an external magnet are provided.

FIG. 1 shows a hyoid bone 100, which is a horseshoe shaped bone situated in the anterior midline of the neck between the chin and the thyroid cartilage. The hyoid bone 100 is a very unique bone, solitary in design, and is the only bone in the human body that does not attach to any other bone. The hyoid bone 100 is located below the mandible and is located in the mid portion of the neck, superior to the larynx and suspended from the styloid process 102 of the temporal bone via the stylohyoid muscles and ligaments.

The hyoid bone has of its body, two posteriorly projecting greater cornua 104 which attach to these ligaments, and two lesser cornua 106 which are located more anteriorly.

The hyoid bone 100 has extensive soft tissue attachments throughout the area, including those to the tongue, epiglottis, and lateral pharyngeal tissues around the throat. The multiple muscle attachments that connect the hyoid bone 100 to these and other structures include the hyoglossus, mylohyoid, sternohyoid, and thyrohyoid muscles, and the hyoepiglottic ligament connects the hyoid to the epiglottis. The attachments between the hyoid bone 100 and other structures of the head and neck enable forces applied to the hyoid bone 100 to be applied to these other structures indirectly.

FIG. 2a-2b show planar schematic views of one embodiment of an orthotic obstructive sleep apnea treatment device 200, where a ferric element 202 (shown in FIG. 2a ) is attached to the hyoid bone 100 using an attachment element 204. According to one aspect of the invention, the ferric element 202 (shown in FIG. 2a ) is disposed to face along a treatment vector 206 from the hyoid bone 100, and the treatment vector is oriented relative to a sagittal plane of a human subject 208.

As shown in FIGS. 2a and 2b , the orthotic obstructive sleep apnea treatment device 200 further includes an external orthotic neck device 210 having a contoured housing 212 with a shape disposed to conform about a neck 214 of the human subject 208, where the housing 212 includes a force delivery element 216 disposed at an exterior-front neck region 220 of the human subject 208 and is disposed to provide an attractive force to the ferric element 204 along the treatment vector 206. According to one aspect of the invention, the patient 208 can prevent or relieve airway obstruction by wearing the neck accessory 210, with its magnetic external component 216, where the external component 216 acts on the internal component 202 through magnetic force. The internal magnetic component 202 is secured to the hyoid bone 100, so moving the internal component 202 causes a corresponding movement of the hyoid bone 100. In a further aspect of the invention, the magnetic attraction between the internal component 202 and the external component 216 is disposed to not block the airway at any point due to misalignment.

FIGS. 3a and 3b show some exemplary embodiments of the external orthotic neck device 210, where FIG. 3a shows the contoured housing 212 holding the force delivery element 216, and FIG. 3b shows the contoured housing 212 holding the force delivery element 216 and further includes a force sensor 300 disposed to measure a force exerted on the hyoid bone 100, a skin contact pressure, tissue compression between the ferric element and the force delivery element, or any combination thereof. According to one aspect of the invention, the housing 212 includes an appropriately programmed microprocessor and memory device 302 disposed to monitor data from the force sensor 300, where the microprocessor and memory device 302 outputs measurement data according to time. In a further aspect the housing includes a visual display 304, where the microprocessor and memory device 302 outputs the measurement data to the visual display 304. Here the visual display 304 can include indicator lights that provide acceptable or unacceptable display signals according to readings from the force sensor 300.

An exemplary attachment element 204 to secure implant device to the hyoid bone 100 is shown in FIGS. 4a-4c . As shown in FIGS. 4b and 4c , the clip 204 geometry matches that of the body of the hyoid bone 100 in order to create the best fit and hold on the bone 100. Superior clip arm 400 (shown in FIG. 4a ) is longer than inferior clip arm 402 (shown in FIG. 4a ) to accommodate the larger bone thickness superiorly. Attachment onto the center of the body of the hyoid 100, as opposed to the Cornu (horns 102/104) or the sides of the body, permit the smallest incision for implantation and the most regularity between patients.

FIG. 4a shows “fingers” 404 cut into the clip 204, where the clip 204 goes around the hyoid 100 and into tissue, prevent excess tissue damage while still providing adequate fixation. In one aspect, the clip 204 can be made of Nitinol material to aid in implantation. In another aspect, the clip 204 can utilize either the super elastic property or temperature shape memory property of Nitinol. To use the super elastic property a tool is used to stretch the clip 204 open to pass over the Hyoid 100. The implantation tool is then relaxed and the clip 204 springs back to its original shape, securing it around the Hyoid bone 100. In another aspect, the temperature shape memory property is used, there the clip 204 is cooled (possibly in an ice bath) and deformed while cool into a shape that will easily fit over the hyoid 100. The clip 204 is then placed on the hyoid 100 and as the heat from the patient 208 warms the clip 204, it reforms back to its original shape and is secured around the hyoid 100.

FIGS. 5a-5c show other exemplary embodiments of the external orthotic neck device invention, where the force delivery element 216 in the housing 210 includes an adjustable force. Here, the force delivery element 216 can include an appropriately programmed microprocessor and memory 302, where the data from force sensor 300 is processed through the appropriately programmed microprocessor and memory 302, and the force is adjusted according to instructions from the appropriately programmed microprocessor and memory 302. Here, the force is adjusted discretely or continuously. In one aspect, the microprocessor and memory device 302 is disposed to provide pattern recognition, where for the pattern recognition, the patterns are not indicative of the quality of sleep, and the current invention recognizes patterns associated with breathing, forces, and other things. In another aspect, the recognized pattern is output to an appropriately programmed computer 500 for analysis. In a further aspect, the force is adjusted according to the recognized pattern. In yet another aspect, the force delivery element 216 includes an electromagnet, where the attractive force is adjusted according to an electrical current. Further, the strength of the electrical current is according to data from the force sensor 300. Additionally, the strength of the electrical current is according to a predetermined pattern, wherein the predetermined pattern comprises data from a pattern analysis.

In another aspect of the invention, the housing includes connectivity to an appropriately programmed external computer and data storage device 500, where the connectivity includes wired connectivity 504 or wireless connectivity 504, and where data from the force sensor 300 is communicated to and from the appropriately programmed computer and external data storage device 500. Further, the sensor data could be communicated via phone system for tracking and/or analysis. In particular, the sensors could be transmitted via Bluetooth to a cell phone (the memory and microprocessor) and then on to the ‘cloud’.

FIG. 6 shows a further aspect of the invention, where the housing 212 includes an inflatable balloon bladder 600 disposed to conform about the neck of a patient 208. In one aspect, the inflatable balloon bladder 600 includes a discrete lumen for localized shape adjustment. In another aspect, the force delivery element 216 includes an appropriately programmed microprocessor and memory 302, where the data from force sensor 300 is processed through the appropriately programmed microprocessor and memory 302, where the inflatable balloon bladder 600 is adjusted according to data from the force sensor 300. In another aspect, the inflatable balloon bladder 600 is filled with air, foam or gel.

FIGS. 7a-7f show some exemplary embodiments of sensors in the external orthotic neck device 210. FIG. 7a shows the external orthotic neck device 210 having a force delivery element 216 disposed on the housing 212, and the force sensor 300 disposed on the skin of the patient 208. FIG. 7b shows the external orthotic neck device 210 having a force delivery element 216 disposed on the force sensor 300, and the housing 212 disposed between the force sensor 300 and the skin of the patient 208. FIG. 7c shows a housing 212 disposed to suspend the force sensor 300 and force delivery element 216 with the housing 212 and the housing 212 is disposed in the skin of the patient 208. FIG. 7d shows the external orthotic neck device 210 having a force delivery element 216 disposed on the inflatable balloon bladder 600, and the force sensor 300 disposed between the inflatable balloon bladder 600 and the skin of the patient 208. FIG. 7e shows the external orthotic neck device 210 having a force delivery element 216 disposed on the force sensor 300, and the inflatable balloon bladder 600 disposed between the force sensor 300 and the skin of the patient 208. FIG. 7f shows the inflatable balloon bladder 600 disposed between the skin of the patient 208 and the housing 212, where the force sensor 300 is disposed in the inflatable balloon bladder 600. Further, a temperature sensor may be provided to measure compliance (hours of use) of the device.

In yet another aspect of the invention, the force delivery element 216 includes an adjustable force, wherein the adjustable force includes a moveable magnet. FIGS. 8a-8d show the housing 212 having an exemplary embodiment of an adjustable force delivery element 800, where FIG. 8a shows an adjustable magnet 802 disposed in a threaded positioning element 804. FIG. 8b shows an adjustable magnet 802 disposed to move according to an inflatable bladder 806, and FIG. 8c shows an adjustable magnet 802 disposed in an indexed positioning element 808. FIG. 8d shows an example of the adjustable magnet 802 disposed in an indexed positioning element 808.

FIGS. 9a-9d show a housing 212 disposed to receive force delivery elements 216 that can be inserted to a cavity 900 in the housing 212. FIGS. 9b-9d show the force delivery element 216 includes a removable magnet, where the housing 212 for the force delivery element is disposed to receive magnets 902 having different magnetic forces. Here the magnets 902 can include different shapes, sizes or materials.

In another aspect of the invention, the force delivery element includes an adjustable magnet disposed to change the treatment vector, where the treatment vector includes a force and a direction.

The present invention has now been described in accordance with several exemplary embodiments, which are intended to be illustrative in all aspects, rather than restrictive. Thus, the present invention is capable of many variations in detailed implementation, which may be derived from the description contained herein by a person of ordinary skill in the art. For example, features of this orthotic device could be applied to treat other diseases and conditions. Possible applications include orthotic devices worn on the torso to apply force to internal magnet(s) on the stomach, bladder or rectum. The direction and magnitude of these forces could be used to alleviate hunger, acid reflux, urination or defecation. Similarly, the force could be use for pain relief by applying force to painful structures in the body.

There are many possible variations in the detailed design of the magnets that could affect the magnitude and direction of the magnetic field. Sample variations would include the use of Hallbach arrays, back iron or pole pieces to focus the field. Assemblies with other ferromagnetic materials could increase or reduce the strength of the magnetic field and change the directional characteristics of the magnet system.

All such variations are considered to be within the scope and spirit of the present invention as defined by the following claims and their legal equivalents. 

The invention claimed is:
 1. An orthotic obstructive sleep apnea treatment device, comprising: a. a hyoid bone attachment element to couple a ferric element to a hyoid bone; b. an external orthotic neck device, wherein said external orthotic neck device comprises a support shaped to confirm about one or more of a neck, a head, or a chest of a human subject, wherein said support comprises a force delivery element, wherein said force delivery element is configured to be disposed at an exterior region of said human subject, wherein said force delivery element provides an attractive or adjustive force to said ferric element; and c. a sensor, wherein said sensor measures a one or more metrics associated with a breathing pattern, a breathing rate, an apnea event, a snoring pattern or a snoring rate.
 2. The obstructive sleep apnea treatment device of claim 1, wherein said force delivery element comprises an electromagnet, wherein an attractive force exerted by said electromagnet is adjustable according to an electrical current.
 3. The orthotic obstructive sleep apnea treatment device of claim 2, wherein an amperage of said electrical current is determined according to (i) data from said sensor or (ii) to a predetermined pattern, wherein said predetermined pattern comprises data from a pattern analysis.
 4. The sleep apnea treatment device of claim 1, further comprising an inflatable bladder between said human subject and support wherein the inflatable bladder can be adjusted manually or automatically to vary the ferric element distance and therewith the attractive or adjustive force.
 5. The sleep apnea treatment device of claim 1, wherein the support comprises a force sensor.
 6. The sleep apnea treatment device of claim 1, further comprising a force frequency sensor to quantify the one or more metrics.
 7. The sleep apnea treatment device of claim 1, further comprising a pulse sensor, an oxygen sensor, an acoustic sensor, an accelerometer sensor, or a touch sensor.
 8. The sleep apnea treatment device of claim 1, further comprising a sensor to detect a physiological position of tissue of said human subject.
 9. The sleep apnea treatment device of claim 1, further comprising a telemetric sensor, wherein the telemetric sensor is magnetic, capacitive or electric field based.
 10. The sleep apnea treatment device of claim 1, wherein the support comprises an embedded microprocessor.
 11. The sleep apnea treatment device of claim 1, wherein said support comprises a processor and a memory device, wherein said processor and said memory device are disposed to monitor data from said sensor, wherein said processor and said memory device outputs measurement data according to time.
 12. The obstructive sleep apnea treatment device of claim 11, wherein said support comprises a visual display, wherein said processor and said memory device outputs said measurement data to said visual display.
 13. The obstructive sleep apnea treatment device of claim 12, wherein said visual display comprises indicator lights, wherein said indicator lights provide acceptable or unacceptable display signals according to readings from said sensor.
 14. The obstructive sleep apnea treatment device of claim 13, wherein said support comprises connectivity to an external computer and a data storage device, wherein said connectivity comprises wired connectivity or wireless connectivity, wherein data from said sensor is communicated to and from said external computer and said external storage device.
 15. The obstructive sleep apnea treatment device of claim 14, wherein said external computer comprises a cellular telephone.
 16. The obstructive sleep apnea treatment device of claim 1, wherein said force delivery element comprises a processor and a memory device wherein data from said sensor is processed through said processor and said memory device, wherein said attractive or adjustive force is adjusted according to instructions from said processor and memory.
 17. The obstructive sleep apnea treatment device of claim 16, wherein said processor and memory are configured to provide pattern recognition, wherein said pattern recognition identifies a pattern associated with breathing rate of the human subject.
 18. The obstructive sleep apnea treatment device of claim 17, wherein a recognized pattern from said pattern recognition is configured to be output for analysis.
 19. The obstructive sleep apnea treatment device of claim 18, wherein said attractive or adjustive force is configured according to said recognized pattern.
 20. The obstructive sleep apnea treatment device of claim 1, wherein said force delivery element comprises an adjustable force element, wherein said adjustable force element comprises a moveable magnet.
 21. The obstructive sleep apnea treatment device of claim 1, wherein said force delivery element comprises a removable magnet, wherein said force delivery element is disposed to receive magnets having different magnetic forces.
 22. The obstructive sleep apnea treatment device of claim 1, wherein said support comprises a localized shape adjustment member, wherein said localized shape adjustment member is disposed to conform about the neck.
 23. The obstructive sleep apnea treatment device of claim 1, wherein said force delivery element comprises a processor and a memory device, wherein data from said sensor is configured to be processed through said processor and said memory device, and wherein an inflatable balloon bladder is configured to be adjusted according to said data from said sensor.
 24. The obstructive sleep apnea treatment device of claim 1, wherein said force delivery element comprises an adjustable magnet, wherein said adjustable magnet is disposed in (i) a threaded positioner or (ii) an indexed positioner.
 25. The sleep apnea treatment device of claim 1, wherein said force delivery element comprises a processor and a memory device both configured to recognize patterns associated with said one or more metrics. 